Protection window for optical sensors in industrial applications

ABSTRACT

This invention describes a method and apparatus for protecting optical sensors in harsh industrial environments, particularly welding and machining. In a preferred embodiment, a sacrificial window is utilized which is replaced as needed. Numerous design features of such windows are disclosed. Other embodiments include protective baffles and other features.

INTRODUCTION

In the development of electro-optical sensors for use in assembly toolsand other applications, protection is required where welding or otherenvironmental contamination is taking place. Some approaches to thisproblem have been described in co-owned pat. Appl. PCT/US94/00398,incorporated by reference, and in copending application Ser. No.08/704,861 filed on even date by Timothy R. Pryor, for FURTHERPROTECTION FOR OPTICAL SENSORS IN INDUSTRIAL APPLICATIONS.

This application is aimed at further protection means, which can bedesirable in many applications. The development here has been developedthrough testing in several automotive factory applications in both spotwelding and arc welding, although the invention comprehends protectionfrom a wide variety of other contamination sources.

BACKGROUND

Machine vision and electro-optical sensors are extremely useful forrapid accurate data gathering from objects, such as parts beingmanufactured. The ability of such sensors to be employed is however,limited by their ability to work in the manufacturing or otherenvironment in question. While problems of EMI, liquids, etc. cangenerally be solved, the more severe environments cause degradation ofthe optical components of the sensor--particularly the front protectivewindow.

There are two kinds of such contamination. The first are thosecontaminants with locally impact or react with the window to adverselyalter its optical characteristics or eventually destroy it. The secondare those which coat the window, seldom destroying it, but generallyreducing optical performance over a larger window region.

An example of the former which has been encountered by the inventorswhere optical sensors are used in car body and other fabricated partsassembly, is window contamination by weld splatter, or drips. Duringwelding, particles of metal, the temperature of which depends on theprocess, are shot off, or fall onto the sensor window--melting, crazing,staining, or otherwise damaging it. The particular problem is damage tothe front window of the sensor which protect the basic optics inside.These windows are typically assumed to be flat and clear, and departuresfrom this condition due to contamination or damage, can change thecharacteristics of the sensor, or kill its operation completely,depending on the optical design.

METHODS OF PROTECTION

There are several methods of protection. The first is to keepcontamination from falling on the window at all. In this case, shuttersand baffles can be used, and some variations of this are describedherein.

The second mode of protection is to have an external window, such asshown in FIG. 1 of this case. This external window is, in a preferredembodiment, is essentially sacrificial, and when it is damaged enough towhere the sensor won't work sufficiently to get accurate informationfrom the parts, or other characteristics being observed, this windowreplaced.

The way in which the external window interacts with the optical sensor,the choice of material, the methods for attaching it to the sensor, thespecifics of its particular location, and other features, are all heredescribed. Other forms of protection are also disclosed such asspecialized covers, magnetic repulsion, and other means.

The invention is more particularly disclosed in the followingembodiments.

FIG. 1 is a diagrammatic view of a first embodiment of a sacrificialexternal window of the invention, and its mounting to a typicaltriangulating sensor.

FIGS. 2 and 3 are diagrammatic illustrations of a portion of the deviceof FIG. 1.

FIG. 4 is a diagrammatic view of a second embodiment of a sacrificialexternal window of the invention, and its mounting to a typical imageanalyzing sensor.

FIG. 5 is a diagrammatic view of a third embodiment of the inventionwhere a protective window is spaced from a window of an optical sensor.

FIG. 6 is a diagrammatic illustration of a modification of an element ofthe device of FIG. 5.

FIG. 7 illustrates other means of protection of the sensor.

FIG. 8 illustrates a sensor having a collapsible protection device,which is compressed by the part being welded to shield the sensor duringwelding from splatter in adjacent areas.

FIG. 9 illustrates an indexable shutter using a shuttle type mechanismand an indexable shutter using a lever action.

FIG. 1 illustrates the basic invention. An electro-optical sensor,typically having lighting, imaging, and detection elements within ahousing is in this case represented by a triangulating optical sensor 1,having a visible light laser diode 2, whose beam is converged by lens 3,onto a zone 4 on the surface of an object 19 such as a sheet metal part.Imaging lens 10, images light from the illuminated zone onto an imageposition sensing detector, such as photo detector array 11. Allcomponents of the sensor are typically within a single housing, 14.Contained as well within the housing, and often flush with its outersurface is a sensor window 15, which protects the elements within.

The invention herein comprehends an additional protection over and abovethat provided by the base sensor window. This protection is particularlythat of a sacrificial window, which can be replaced by the user asrequired.

Typically this sensor 1, is located within a welding assembly tool, suchas 20, a section of which is here shown. In this section, two pieces ofsheet metal 18 and 19 are clamped together by clamp 21, against alocator block 22, and a spot weld gun, having two tips, 25 & 26, is usedto both urge the metal together, and to put a large current through themetal, causing it to locally melt and thus fuse together, producing a"spot weld".

When such spot welding occurs, typically under currents as high as60,000 amperes, if the tips are not well prepared and aligned, sparksare generated comprised of tiny bits of molten metal, which fly out inall directions

As discussed in the referenced copending applications, a sacrificialwindow such as 50 can be placed to absorb or deflect such splatter,preventing it from hitting the window of the sensor unit, 15, possiblypenetrating same, and destroying the device, or at a minimum generally,altering its performance in a deleterious manner. The sensor unit canthus be protected with the sacrificial window replaced as necessary.

We have found in practicing this invention that the ease of replacementof the window in its proper location is essential for customeracceptance. Replacement is after all an added maintenance operation ofthe welding line, and not taken lightly by the plant personnel. For thisreason special types of window mounting arrangements have beendeveloped, here disclosed.

As shown, the window 50 has two round magnetic portions, 60 & 61, whichin turn are attracted to the magnetic portions of the housing, 63 & 62.While all of the above, elements 60-63 can be magnets, generally onlyone of the two opposing faces needs itself be magnetic, the other beingferrous or other suitable material. However typically, both aremagnetic, as many of the sensor housings used are aluminum, or in somecases plastics, and thus do not provide a suitable material surface.Note that more or less magnets can be used, with the choice generallybeing the minimum number suitable to sufficiently secure the window inquestion.

A key part of this invention, besides the ease of the magneticsnap-on/snap-off characteristic of this window, is that the roundmagnets utilized are self-aligning. As the operator places the window inposition, it "snaps" into correct alignment. Alternative means ofalignment are also possible, such as tapered pins.

Note that round magnets 62 and 63 can, if desired be recessed slightlyin the front of housing 14, such that opposite pole magnets 60 and 61 onthe window 50 can fit into the recess so as to better align the window.Alternatively, but less preferred, magnets 62 and 63 could protrude, andfit into recesses in window 50.

While perfect alignment is not necessarily required, it should be notedthat many electro-optical sensors, such as the triangulating onesdescribed above, have been developed to measure highly accurately oversignificant ranges, using essentially the optical deviation of visibleor infrared images. Since the window is a refractive element, if it isout of position it can disturb the calibration of the sensor.

The sacrificial window is preferably thin, and flat, so that it does notsignificantly disturb the calibration by extending the image distance orwarping the optical axis, for example. It is desirably close to thesensor window, and, in turn, preferably to the imaging lens as well,itself often located near the sensor window inside the housing.

A preferable sacrificial window is 1 mm or less in thickness, locatedwithin 1 mm of the sensor window. However, it can be noted that suchwindows, when thicker, are desirably more difficult to melt through,although optical distortion even in the surface can shut the sensor downin certain cases, without total destruction of the window.

We have found in practicing the invention with imaging type sensorslocated in welding tools, that the sacrificial window is preferablywithin 40 mm from the imaging optics. A sacrificial window material wehave found useful is acrylic plastic.

FIG. 1b shows a sheet metal hole or other image analyzing sensor, 100,including imaging lens 101, matrix array camera 131 connected tocomputer 132, and part illuminating lights, 102, where the lights arealso covered by the sacrificial window, 105, in this case attached by"velcro" (or other suitable hook and eye or other type material) strips110 and 111, to housing 100, and if desired, aligned in this case usingtapered pins 120 in housing hole 130.

Less desirably, multiple sacrificial windows can be used on differentportions of a sensor, where imaging and transmitting optics are forexample widely spaced. This makes more effort for maintenance personal,as more changing operations are involved.

FIG. 5 illustrates a sacrificial window, 200, or for that matter apermanent window (if it can withstand the environment), spaced with anair gap of width, W, with respect to the front window, 205, of sensorhousing, 206--in this case of a triangulation ranging type opticalsensor, or other type optical sensor.

As noted above, it is desirable for sensor calibration purposes that "W"be minimized. However, in very adverse environments, it may be desiredto space the sacrificial window a larger distance W, in order that weldsplatter, or other material, melting through or other wise penetratingthe sacrificial window does reach the window of the housing. To furtherencourage this to be the case, air flow 201 from jet 202, in this caseattached to the sensor housing, is directed across the back side of thewindow, through the air gap, W. This tends to cool the window 200 (and205 as well) and prevent it from melting.

As shown in FIG. 6, the protective window 200 can also be tilted at anangle, theta, with respect to the sensor window 205 (inset) in orderthat molten material can be deflected off, and/or fall off, withouthitting window 205.

In a further system for an even more hazardous environments, air blow201 is forced over the front of the sacrificial window in order to urgeundesirable material to fall off, as opposed to stick, and further tocool the material and window even more, postponing the point at whichmelting the window occurs (and the window has to be replaced).

With such air blow type systems, it is generally important that dry airbe used, or another dry gas, such that moisture from the blow-off action(often present if compressed air traveling through shop floor lines isused) does not itself contaminate the window.

FIG. 7 illustrates other means of protection of the sensor in operation.In this particular figure, the sensor beam path 300 of triangulatingsensor 301 with output window 302 is essentially enclosed, by springloaded collapsing metallic tube 310. Alternatively an elastic rubber"boot" may be used instead of a tube.

As the part 320 to be welded is loaded into the welding station (notshown for clarity), it is loaded over the telescoping tube 310,compressing it and leaving no air space for the weld splatter to enter.This works for sensors whose optical axis is generally in the directionof part load, unload (usually vertical, but not always).

If the parts cannot be loaded in such a manner, slides can be providedto index the collapsing tube or other baffle in order to partly or fullyenclose the beam path. Or shutter mechanisms can be employed by placinga protective metallic plate in front of the output window 302 of thesensor.

An alternative method is illustrated in FIG. 8 in which the sensor 400is located on a slide or other suitable conveyance, 401, and moved inand out of position, with respect to the object to be measured 405,which itself may be welded by MIG weld torch 410, for example. When itis out of position (dotted lines) it can be covered over, for example byhousing 420, in such a way as to out of the danger of the weld splatterduring welding (the sensing being used only before and after welding).

Another approach, illustrated in FIG. 9, includes a programmable leverunit 500 that flips a sensor 501 into position relative to part to bemeasured 504, and then removes it from harm's way.

A rotary lever unit such as 509, can alternatively be used to move, oncommand, a shuttering device into position. This is shown whereinanother sensor 510 also used to determine location of part 504, has ablocking hat 525 placed over it during welding by rotary unit 509 Suchtechniques can be used to protect against machining coolants and thelike during machining, and for shielding sensors during other working.

Note that it is also possible to have a window material which canincorporate metallic or magnetic material properties into the glass,plastic or other window material, such that the window itself can bemagnetically or otherwise attracted to the sensor housing. For examplesmall permanent magnets 65 and 66 may be positioned in the housing.

In this invention, the terms optical sensor, and light, include allelectromagnetic wavelengths, ultraviolet to infrared inclusive.

What is claimed is:
 1. Assembly tool apparatus comprising:assemblytooling for industrial assembling of an object; an electro-opticalsensor mounted in the apparatus for obtaining data relative to assemblyeffected by the assembly tooling, said electro-optical sensor comprisinga housing having an optical window and having an optical sensor mountedin the housing in position to optically sense, through said opticalwindow, an aspect of assembly effected by said tooling, saidelectro-optical sensor being positioned in said tooling such that theoptical window of said housing is subject to environmental contaminationcreated during operation of said assembly tooling to assemble theobject, said contamination being such as to cause degradation of theoptical properties of said optical window; and a protection windowmounted in the apparatus in a protection position to protect saidoptical window from said contamination, said protection window beingreadily releasably mounted in said apparatus by attachment means whichpermit easy removal of said protection window from said protectionposition by hand and which permit easy mounting of a protection windowin said protection position by hand.
 2. Apparatus according to claim 1wherein said attaching means comprises magnetic attaching means. 3.Apparatus according to claim 1 wherein said attaching means compriseshook and loop fasteners.
 4. Apparatus according to claim 1 wherein saidattaching means comprises means for aligning said protection window insaid position.
 5. Apparatus according to claim 2 wherein said attachingmeans comprises means for aligning said protection window in saidposition.
 6. Apparatus according to claim 2 wherein said magneticattachment means comprise permanent magnets mounted on at least one ofsaid windows and said housing.
 7. Apparatus according to claim 2 whereinsaid attachment means comprises permanent magnets having an outer planarsurface mounted on said housing such that the outer planar surface ofsaid magnets is flush with an outer surface of said housing. 8.Apparatus according to claim 1 wherein said protection window, when insaid position, is in close proximity to said optical window and paralleltherewith.
 9. Apparatus according to claim 1 wherein said protectionwindow, when in said position, is spaced from said optical window. 10.Apparatus according to claim 1 wherein said protection window, when insaid position, is disposed at an angle with respect to said opticalwindow.
 11. Apparatus according to claim 1 wherein said protectionwindow comprises plastic.
 12. Apparatus according to claim 2 whereinsaid protection window comprises magnetic or magnetizable material. 13.Apparatus according to claim 11 wherein said assembly tool apparatuscomprises welding means and wherein said environmental contaminationcomprises weld splatter.
 14. Apparatus according to claim 11 whereinsaid protection window is mounted on said housing of saidelectro-optical sensor.
 15. Apparatus according to claim 14 wherein saidattachment means comprises magnetic attachment means.
 16. Apparatusaccording to claim 14 wherein said attachment means comprises hook andloop fasteners.
 17. Apparatus according to claim 11 wherein saidprotection window consists essentially of an optically transmittingmember and said attachment means.